25

Suppose I have a constant defined in a header file

#define THIS_CONST 'A'

I want to write this constant to a stream. I do something like:

char c = THIS_CONST;
write(fd, &c, sizeof(c))

However, what I would like to do for brevity and clarity is:

write(fd, &THIS_CONST, sizeof(char)); // error
                                      // lvalue required as unary ‘&’ operand

Does anyone know of any macro/other trick for obtaining a pointer to a literal? I would like something which can be used like this:

write(fd, PTR_TO(THIS_CONST), sizeof(char))

Note: I realise I could declare my constants as static const variables, but then I can't use them in switch/case statements. i.e.

static const char THIS_CONST = 'A'
...
switch(c) {
  case THIS_CONST: // error - case label does not reduce to an integer constant
    ...
}

Unless there is a way to use a const variable in a case label?

4
  • 1
    The only thing that springs to mind is a linker trick. What compiler are you using? If you can introduce some absolute pointer values into your linker commands, you could use, e.g., (void *)0x00000004 as an integer value '4' and also as a character. It's not portable. If you're on Windows, check into the C++ constructor list named .cxa - .cxz used by the MS Visual C standard C library during initialization. That is similar to the kind of linker trick I am talking about. The difference would be causing the output image to contain some non-relocatable addresses which you can cast to int.;) Commented Oct 14, 2009 at 7:29
  • Interesting idea - that's a little more skull-duggery than I was looking for, but interesting nonetheless. I'm using gcc and my code has to compile under Linux and Solaris :)
    – James
    Commented Oct 14, 2009 at 7:35
  • 1
    Aside from wanting to use it in a case statement, why else do you need it? In one of your answers below you said you also wanted it to apply to floats, but you can't use a float as a case statement expression anyway. Commented Oct 14, 2009 at 7:58
  • Good point about floats - but ints still apply. The only need I have is for it in a case statement. However this question was motivated not so much by 'needing it', but just wanting to see if it was possible via some C macro trickery (and being well aware that a literal is not the same as a variable and cannot have its address taken). Anyway thank you all for your contributions - I guess the short answer is 'no', there is no accepted trick for getting the compiler to place a literal value into a memory location and obtain a pointer to it, and no clean & threadsafe way to do it at runtime.
    – James
    Commented Oct 14, 2009 at 23:55

12 Answers 12

45

There is no way to do this directly in C89. You would have to use a set of macros to create such an expression.

In C99, it is allowed to declare struct-or-union literals, and initializers to scalars can be written using a similar syntax. Therefore, there is one way to achieve the desired effect:

#include <stdio.h>

void f(const int *i) {
    printf("%i\n", *i);
}

int main(void) {
    f(&(int){1});
    return 0;
}
3
  • 1
    Took me a while to get to this, but yes this does exactly what I was talking about! Thanks!
    – James
    Commented Nov 8, 2010 at 23:52
  • 10
    These kind of constructions are called compound literals (ISO/IEC 9899:TC3, p75, §6.5.2.5, ¶4). I've managed to track down this information via this answer. Thanks! I hope the reference to the C99 specification will be of use to someone in the future! Commented Nov 13, 2011 at 6:43
  • "In C99, it is allowed to declare struct-or-union literals" --> No, since C99, allowed to declare compound literals. Commented Mar 28, 2020 at 23:28
16

These answers are all outdated, and apart from a comment nobody refers to recent language updates.

On a C99-C11-C17 compiler using a compound literal, http://en.cppreference.com/w/c/language/compound_literal, is possible to create a pointer to a nameless constant, as in:

int *p = &((int){10});
1
  • 6
    The accepted answer explicitly refers to C99 and uses a compound literal (although it could be improved to use the proper term 'compound literal' instead of 'struct-or-union literal')
    – James
    Commented May 10, 2018 at 22:33
5

The only way you can obtain a pointer is by putting the literal into a variable (your first code example). You can then use the variable with write() and the literal in switch.

2
  • I was hoping for a macro to do the 'put the literal into variable and obtain pointer to it' part, but since no threadsafe solutions have been put forward, I'm accepting this as the simple answer to my question.
    – James
    Commented Oct 15, 2009 at 0:06
  • 1
    @ JeffH: I can understand you can't be bothered to explain why you downvoted a downright silly answer. But I don't think my answer qualifies as such, so it can't be "bad form", "bad language" or "doesn't apply at all", but someone took exception at the content of my answer. In such cases, I think a comment is in order...
    – DevSolar
    Commented Oct 15, 2009 at 7:03
4

C simply does not allow the address of character literals like 'A'. For what it's worth, the type of character literals in C is int (char in C++ but this question is tagged C). 'A' would have an implementation defined value (such as 65 on ASCII systems). Taking the address of a value doesn't make any sense and is not possible.

Now, of course you may take the address of other kinds of literals such as string literals, for example the following is okay:

write(fd, "potato", sizeof "potato");

This is because the string literal "potato" is an array, and its value is a pointer to the 'p' at the start.

To elaborate/clarify, you may only take the address of objects. ie, the & (address-of) operator requires an object, not a value.

And to answer the other question that I missed, C doesn't allow non-constant case labels, and this includes variables declared const.

1
  • 2
    In C, 'A' is not a literal, but a constant. C has 2 kinds of literals: string literal and compound literal. Both of those two can have their address taken, unlike constant 'A'. Commented May 8, 2017 at 14:29
3

Since calling write() to write a single character to a file descriptor is almost certainly a performance killer, you probably want to just do fputc( THIS_CONST, stream ).

1
  • Thanks, that's a good point, I hadn't thought of that. However, this does not extend to literal ints, floats, etc. Also, I can't actually use fputc in current situation - I didn't mention this in the question, but I am actually calling a function which is a wrapper around write(), and all data must pass through this wrapper function.
    – James
    Commented Oct 14, 2009 at 7:26
3
#define THIS_CONST 'a'

Is just a macro. The compiler basically just inserts 'a' everywhere you use THIS_CONST. You could try:

const char THIS_CONST = 'a';

But I suspect that will not work wither (don't have a c-compiler handy to try it out on, and it has been quite a few years since I've written c code).

4
  • That's the best answer I've seen so far. It makes sense, solves the problem, and improves the code in other aspects, too.
    – sbi
    Commented Oct 14, 2009 at 8:14
  • sbi: except james himself already gave this solution in his question, and also gave the reason why he din't like it
    – Toad
    Commented Oct 14, 2009 at 9:08
  • Ah, I missed that. But now I wonder: C++ allows using consts as case labels. Doesn't C?
    – sbi
    Commented Oct 14, 2009 at 13:29
  • It doesn't. C doesn't have the weird C++ semantics where const mostly means "readonly", and sometimes means "compile-time literal constant". In C, it's always the former - a const variable is read-only from the point of initialization, but it is not a compile-time constant. Which is why all C libraries use #define for true constants. Commented Oct 14, 2009 at 21:13
2

just use a string constant, which is a pointer to a character, and then only write 1 byte:

#define MY_CONST_STRING "A"

write(fd, MY_CONST_STRING, 1);

Note that the '\0' byte at the end of the string is not written.

You can do this for all sorts of constant values, just use the appropriate hex code string, e.g.

#define MY_CONST_STRING "\x41"

will give also the character 'A'. For multiple-byte stuff, take care that you use the correct endianness.

Let's say you want to have a pointer to a INT_MAX, which is e.g. 0x7FFFFFFF on a 32 bit system. Then you can do the following:

#define PTR_TO_INT_MAX "\xFF\xFF\xFF\x7F"

You can see that this works by passing it as a dereferenced pointer to printf:

printf ("max int value = %d\n", *(int*)PTR_TO_INT_MAX);

which should print 2147483647.

2
  • I like the idea here, I hadn't though of using hexadecimal escape codes in a string like that. The best solution I've seen aside from using a compound literal. Thanks for the suggestion.
    – James
    Commented Nov 9, 2010 at 0:35
  • (int*)PTR_TO_INT_MAX has 2 more problems. Casting to int* may not satisfy alignment requirements. "\xFF\xFF\xFF\x7F" is endian sensitive. Commented May 8, 2017 at 14:42
1

For chars, you may use extra global static variables. Maybe something like:

#define THIS_CONST 'a'
static char tmp;
#define PTR_TO(X) ((tmp = X),&tmp)

write(fd,PTR_TO(THIS_CONST),sizeof(char));
1
  • 1
    Yes, this is the sort of thing I was thinking of - only it's not threadsafe.
    – James
    Commented Oct 14, 2009 at 23:52
0

There's no reason the compiler has to put the literal into any memory location, so your question doesn't make sense. For example a statement like

int a;
a = 10;

would probably just be directly translated into "put a value ten into a register". In the assembly language output of the compiler, the value ten itself never even exists as something in memory which could be pointed at, except as part of the actual program text.

You can't take a pointer to it.

If you really want a macro to get a pointer,

#include <stdio.h>
static char getapointer[1];

#define GETAPOINTER(x)  &getapointer, getapointer[0] = x

int main ()
{
    printf ("%d\n",GETAPOINTER('A'));
}
9
  • If there's something wrong with my answer, please leave a comment to let me know what.
    – user181548
    Commented Oct 14, 2009 at 7:15
  • Your answer makes no sense and you did not contribute anything to the actual problem, hence the downvotes. Commented Oct 14, 2009 at 7:17
  • I understand a literal may not be ordinarily put into a memory location, for example it could be encoded directly into an instruction. However, I'm looking for a way to convenient make the compiler put the literal into a memory location and give me a pointer to it, to make my code clearer and shorter.
    – James
    Commented Oct 14, 2009 at 7:19
  • Also your answer is wrong. Your code actually translates to: * register a during compile time as a symbol. * whenever a is referenced use the value it is pointing at. * whenever referenced with & get the memory address instead of the value. Commented Oct 14, 2009 at 7:19
  • And since "char" actually is just a number, you won't have any "literals" in memory. Commented Oct 14, 2009 at 7:20
0

I can see what you're trying to do here, but you're trying to use two fundamentally different things here. The crux of the matter is that case statements need to use values which are present at compile time, but pointers to data in memory are available only at run time.

When you do this:

#define THIS_CONST 'A'
char c = THIS_CONST;
write(fd, &c, sizeof(c))

you are doing two things. You are making the macro THIS_CONST available to the rest of the code at compile time, and you are creating a new char at runtime which is initialised to this value. At the point at which the line write(fd, &c, sizeof(c)) is executed, the concept of THIS_CONST no longer exists, so you have correctly identified that you can create a pointer to c, but not a pointer to THIS_CONST.

Now, when you do this: static const char THIS_CONST = 'A'; switch(c) { case THIS_CONST: // error - case label does not reduce to an integer constant ... }

you are writing code where the value of the case statement needs to be evaluated at compile time. However, in this case, you have specified THIS_CONST in a way where it is a variable, and therefore its value is available only at runtime despite you "knowing" that it is going to have a particular value. Certainly, other languages allow different things to happen with case statements, but those are the rules with C.

Here's what I'd suggest:

1) Don't call a variable THIS_CONST. There's no technical reason not to, but convention suggests that this is a compile-time macro, and you don't want to confuse your readers.

2) If you want the same values to be available at compile time and runtime, find a suitable way of mapping compile-time macros into run-time variables. This may well be as simple as:

#define CONST_STAR '*'
#define CONST_NEWLINE '\n'

static const char c_star CONST_STAR;
static const char c_newline CONST_NEWLINE;

Then you can do:

switch(c) {
  case CONST_STAR:
    ...
    write(fd, &c_star, sizeof(c_star))
    ...
}

(Note also that sizeof(char) is always one, by definition. You may know that already, but it's not as widely appreciated as perhaps it should be.)

3
  • I can't the #define lines formatted correctly. And advice on what I'm doing wrong, please?
    – Tim
    Commented Oct 14, 2009 at 7:45
  • Thanks for your detailed response Tim. My question wasn't arising from a misconception of the difference between values of variables at runtime and compile time constants, but rather looking for syntactic sugar to give me both a compile time constant and a runtime variable containing that constant with minimal leg-work.
    – James
    Commented Oct 14, 2009 at 7:46
  • @Tim: Code formatting is broken within lists. Annoying, I know. The way to get around this is to insert a simple paragraph before the code.
    – sbi
    Commented Oct 14, 2009 at 17:12
0

Here is another way to solve this old but still relevant question

#define THIS_CONST 'A'

//I place this in a header file
static inline size_t write1(int fd, char byte)
{
    return write(fd, &byte, 1);
}

//sample usage
int main(int argc, char * argv[])
{
    char s[] = "Hello World!\r\n";
    write(0, s, sizeof(s));

    write1(0, THIS_CONST);

    return 0;
}
-2

Ok, I've come up with a bit of a hack, for chars only - but I'll put it here to see if it inspires any better solutions from anyone else

static const char *charptr(char c) {
    static char val[UCHAR_MAX + 1];
    val[(unsigned char)c] = c;
    return &val[(unsigned char)c];
}

...

write(fd, charptr(THIS_CONST), sizeof(char));
8
  • For starters, you'd want to replace 256 by UCHAR_MAX. I'm not entirely certain it's threadsafe, but it certainly uses a lot of memory. (guesses, not my downvote)
    – MSalters
    Commented Oct 14, 2009 at 11:40
  • It's ugly as hell, and using a magic number, and wasting 255 bytes of perfectly good memory worst-case, and adding a function call-and-return to what should be a next to trivial operation...
    – DevSolar
    Commented Oct 14, 2009 at 16:12
  • 1
    Fair enough. I think you missed the point though, I was just putting forward the concept. To avoid the function call and make it threadsafe you could prepopulate a static array and then just have a macro to get the correct offset into the array. And wasting 256 bytes of memory is not an issue in the vast majority of cases. And yes it should be (UCHAR_MAX+1), fair enough - this was just a quick hack to make a point.
    – James
    Commented Oct 14, 2009 at 23:28
  • What was the point of using an array, when you re-initialize the value on every call anyway? Why not just a static char val variable? What was the point of that static array, can you explain? Commented Aug 9, 2010 at 20:33
  • 1
    ..Actually, I just tested the code and it works fine (non-multithreaded). No pointers getting overwritten with different values on subsequent calls. People describe this as 'ugly' and 'a monstrosity' - but actually a function like this eliminates the need for a temporary variable every time you need a pointer to a value you know is going to be constant - that's what I call ugly! Anyhow, the best solution of all is Alek's answer, which solves the problem for all data types without a function call.
    – James
    Commented Nov 9, 2010 at 0:24

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